Fire Sprinkler Design Engineer in Palos Park

When you re looking for a reliable Fire Sprinkler Plumbing Design Experts near Palos Park Illinois? The one to go to is NY-Engineers.Com. Not only for Fire Sprinkler Plumbing Design Experts but also MEP Engineering and HVAC Firms in Chicago. Contact us at 312 767-6877

Nowadays when you approach any contracting company or building owner anywhere from Galewood to Stateway Gardens, about a reliable HVAC Engineering in Chicago, the most popular answer is call NY-Engineers.Com. What is so well known is that NY Engineers is probably your top choice for anyone looking for a fire sprinkler system engineer in Palos Park. At NY Engineers our team has many years of experience designing fire protection and sprinkler systems from North Tonawanda to Rotterdam, NY. Today, from our Chicago office we are helping contractor and developers in Palos Park design the fire protection and sprinkler systems they need.

The possibility of a building burnt down because of fire is really a sight that nobody wants to have. That is the reason why fire protection engineers are hired before a building or apartment is created. Should you be wondering who needs fire protection engineer, then your first name that you should know may be the architect of your building. Exactly like an architect is important to make sure that the style of your building is ideal and safe from all ends; a fire protection engineer ensures that the building is protected from possible probability of fire.

Seeing immediate response from your firefighting pros is okay but won’t it be fantastic if the fire never took place? You should think of “what if” as opposed to going through the dreadful experience of the building catching on fire. Fire protection engineers check out the design of the construction first and then plan the escape paths to be taken in a fire. Additionally, they are accountable for putting in several fire protection things in and outside the building. Water hoses and pipes attached to the main water tank, and checking the fitness of the fire extinguishers are a few of the duties that the fire protection engineer carries out if they are hired.

The Fire Protection Engineers Society has a precise concise explanation of Fire Protection Engineers vs Tech. Both positions call for a solid education in fire technology and skill being a firefighter in many instances.

The engineers use principles to use methods and systems setups in different structures that can help protect people and animals from harm during fires. Engineers study the location where the biggest fire hazards lie and the best places to install protection including sprinklers. They make certain that the use of structures as well as any materials in them are made to keep risks to a minimum.

Engineers may also oversee the connection and repair of alarm systems, smoke detectors, and will do investigations of fires after one occurs. This can help them prevent such things from happening in the future.

This kind of title uses scientific principles to help enhance the safety of folks in commercial buildings. A fire technician functions is to conduct the testing and repair of the systems which have been arranged and organized from the engineers.

These individuals also needs to hold the right education and firefighting knowledge to function in the field. They may work to help install sprinklers and fire alarm systems nevertheless they tend not to arrange the design of these systems like the engineers do. There is a great possibility you would like more details on fire sprinkler system engineer services in Palos Park by New York Engineers we invite you to stop by at our Chicago CAD to Revit Modeling blog.

New Electrical Engineering Related Post

Radiant Heating Systems: Types and Applications for HVAC Engineering

Radiant heating systems deliver heat through the floor, walls or ceiling of a building. As implied by their name, these HVAC engineering systems rely mostly on radiant heat transfer – direct delivery of heat from a warm surface to occupants and objects via radiation.

Radiant floor heating systems are characterized by their silent operation and energy efficiency. Since the heat source is located below, temperature rise is uniform as warm air rises and displaces cooler air. This also allows heating to occur without a forced air system: the installation does not disturb dust and allergens, while improving occupant comfort by eliminating air drafts.

Radiant floor heating also offers a lower running cost than furnace-based heating systems – you can expect savings from 25% to 50% according to the US Department of Energy. Space heating is the highest energy expense in certain buildings, so projects that improve its efficiency tend to have an excellent return on investment.

Radiant floor heating is a great option for houses with children and for schools. Conventional air duct systems deliver heat from above, and the lower portion of the room is not always heated effectively because warm air tends to rise. Due to their shorter height, kids are more susceptible to uneven heating from forced air systems, and this can potentially lead to health issues. On the other hand, radiant floor heating delivers heat from the bottom up and improves comfort for kids.

Radiant heat systems are highly recommended HVAC engineering solutions in houses with big rooms and high ceilings. Conventional forced air systems are impractical in these cases, since they only tend to heat the upper portion of the room, wasting energy.

Radiant floor heating systems can be classified based on the medium used to deliver heat: air-heated, electric and hydronic.

1) Air-heated radiant floor system: In this system configuration, hot air is blown through the ducts beneath the floor, which causes a warming effect. The main limitation is that air cannot hold much heat, so these systems are not suited for residential buildings.

2) Electric radiant floor system: This configuration uses heating cables or conductive plastic mats that are built into the floor. The main limitation of electric radiant floor systems is their dependence on resistance heating, which can result in a very high running cost if the kilowatt-hour price is high.

Electric radiant floor heating works best for property owners that have access to time-of-use electricity rates and floors with a large thermal mass (e.g. concrete). The system can be configured to operate when electricity prices are low, which is normally during off-peak hours, storing as much heat as possible in the floor itself.

The system is also set to shut down during peak demand hours with expensive electricity, and the floor can deliver from 8 to 10 hours of heating without power consumption if its thermal mass is high enough. If the floor has a reduced thermal mass, the electric RFH system must operate more frequently, and running costs can increase dramatically during peak demand hours.

3) Hydronic (hot water) radiant floor system: This is the most popular and cost-effective among the three types of radiant floor systems, and is suitable for applications where occupants can use a thermostat to control the heat output room-by-room. Hot water from a boiler is pumped through hydronic pipes that are evenly distributed under the floor, and distribution among different piping runs is controlled through a manifold. Hydronic RFH systems have minimal maintenance requirements and can be installed between the joists under existing floors, making them ideal for renovations.

Radiant Floor Heating Installation Types

Radiant floor heating systems can be classified into wet and dry installations. Note that this classification is independent from the heat transfer medium: the words wet and dry to not make reference to hydronic piping or electrical resistance.

1) Wet installation: This is the oldest type of radiant floor installation. Electrical cables, mats or hydronic tubing are embedded in a thick concrete slab or thin concrete subfloor, which means this installation type is more expensive than a dry one. The RFH system takes more time to heat the floor and the air in the room, but the large thermal mass of concrete preserves the heating effect for several hours after the system is turned off.

2) Dry installation: A dry installation is easier to set up, less expensive and generally the most convenient type. The heating cables, mats or tubing are installed in a pocket of air under the floor, not embedded in concrete, resulting in a faster heating than a wet installation. This system configuration needs to operate at a high temperature however, since it is not embedded in the floor material.

How Flooring Materials Influence Performance

The performance of radiant floor heating is strongly influenced by the flooring material: thermally-conductive materials enhance performance, while insulating materials are detrimental. However, this does not imply you should avoid insulation – just make sure it is not installed where it can block heat transfer between the radiant floor system and indoor spaces.

Due to its high thermal conductivity and storage capacity, ceramic tile is considered the most effective covering material for radiant floor heating. Other materials such as vinyl and linoleum sheet provide too much insulation, hence reducing system efficiency. Wood floors conduct the heat quite well, but laminated wood flooring is prefered over solid wood, which can easily dry and contract.

How Do Radiant Panels Work?

Unlike radiant floor systems, these panels are generally installed in walls and ceilings, using electricity or hot water to heat aluminum sheets. Electrically-heated systems offer the convenience of preventing water leakage issues, but also have a much higher running cost due to dependence on electricity. Radiant panel systems can have a superficial construction or can be embedded in the wall, but keep in mind that future alterations are impractical in the second case.

What Are the Key Components of Radiant Floor Heating Systems?

1) PEX tubing/heating cables/heating mats: This part of the system is responsible for delivering heat. PEX tubing distributes hot water from a boiler, while the other two options produce heat directly through electrical resistance.

2) Manifold: Distributes hot water among various hydronic piping circuits.

3) Actuator valves and fittings: Valves allow water flow control, while fittings provide a connection between piping runs and other system components.